integrated hydrogen production, purification & compression ... · timeline h project start date...
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H2E
Integrated Hydrogen Production, Purification and Compression System
Satish TamhankarThe BOC Group, Inc.
May 24, 2005
Project ID# PD8
This presentation does not contain any proprietary or confidential information
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H2EDOE Merit Review - PD8
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Overview
Timelineh Project start date - April 1, 2005h Project end date - March 31, 2008h Key Milestones
> Techno-economic study - 9/05> Proof-of-concept prototype - 9/06> Advanced prototype - 11/07> Final report - 3/08
Barriers addressedh Cost reduction of distributed
hydrogen production from natural gas and renewable liquids
h DOE delivered H2 cost target:− $1.50/gge H2* in 2010
* Being revised by DOE
Budgeth Total project funding - $3,840,009
− DOE share - $2,854,202− BOC/MRT/HERA share - $985,807
h Funding received in FY04 - noneh Funding for FY05 - $330,410
Partnersh Key partners: MRT and HERA USAh Other collaboration/interactions:
− Safety experts− Product certification experts
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Program Objectivesh To demonstrate a low-cost option for producing FCV quality hydrogen
that can be adopted to meet the ultimate DOE cost and efficiencytargets for distributed production of hydrogen
h Develop a hydrocarbon fuel processor system that directly produces high pressure, high-purity hydrogen from a single integrated unit
− Verify cost and performance targets for the prototype development stages based on techno-economic analysis and develop a plan to address safety issues
− Build and experimentally test a Proof of Concept (POC) integrated reformer/Metal Hydride (MH) compressor system
− Build and demonstrate an Advanced Prototype (AP) system at a commercial site
− Complete final product design capable of achieving DOE 2010 H2 cost and performance targets
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Approach
h Integrate the membrane reformer developed by Membrane Reactor Technology (MRT) and the hydride compression system developed by HERA USA in a single package− Lower capital cost compared to conventional fuel processors by
reduced component count and sub-system complexity tight thermal integration of all reactions/processes in a single packageintegrated, thermal MH compression without rotating machinery, which results in high reliability and low maintenance
− High efficiency achieved bydirectly producing high-purity hydrogen using high temperature, H2 selective membranesimproved heat and mass transfer due to inherent advantages of fluidized catalyst bed designequilibrium shift to enhance hydrogen production in the reformer by lowering the partial pressure of hydrogen in the reaction zoneimproved thermal efficiency and lower compression energy by integrating compression with the reactor system
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Current Forecourt Fueling Station Scenario
Natural GasMethanolGasoline/Diesel
PSA
Water FuelProcessor
HP H2 Storage Tubes
Water
Fuel Dispenser
CompressorPurificationShiftConverter
SyngasH2, CO, CO2, N2
CO2, N2H2, CO2, N2 H2 (99.99%)
CO + H2O
CO2 + H2
SMRATRPOX
Fuel Cell Bus
5 system boxes3 to 5 suppliers
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Forecourt Fueling with Proposed System
Natural GasLPG
Hydride Thermal Compressor
Water FuelProcessor
Fuel Dispenser
Compression
CO2, N2
MembraneReactorAir
H2 (99.9999%)
1 system box1 supplier
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H2EDOE Merit Review - PD8
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Membrane Reactor ConfigurationEffluent Gases
Membrane Module
Oxidant
Typical membranemodule
Energy
H2 product
Steam & H/C
Fluidized bed reactorWell-mixed catalyst particles; uniform temperature
Thermodynamic equilibrium shift of reforming and shift reactionsOxidant added to supply part or all of the energy needed for reformingHydrogen withdrawn with vacuum to increase production
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Membrane Reactor Technology Statush Core technologies in reactor and membrane areas covered by patents
h Fluidized catalyst development complete
h Extensive knowledge / experience with Pd alloys and fabrication / operation of foil and deposited membranes in the 5 - 50 micron range
h Pilot manufacturing system for membrane module in place and operational
h Proof-Of-Concept (POC) scale testing of FBMR technology completed last year with Alpha test unit
Alpha Unit• Located at NRC facility in Vancouver, BC
• Validation of membrane reactor at 15Nm3/hr scale
• Successful operation with custom-developed mechanical vacuum pump
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Basics of Hydride Compression
0.0 0.2 0.4 0.6 0.8 1.0 1.20.1
1
10
100
50
5
0.5
25oC
175oC
100oC
40oC
70oC
Pres
sure
, Atm
H2
Hydrogen:Metal Atomic Ratio
Thermal Compression withMetal Hydride Alloys
Hydrides are materials that store hydrogen
The pressure of the hydrogen is a function of temperature
A modest increase in temperature results in a large increase in pressure
Compression energy can be provided by hot water, rather than electrical power
High compression ratios are achieved by staging alloys with increasing plateau pressures
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Principle of Hydride Compressor
Thermal Compression with Metal Hydride Alloys
HydrideAlloy
Cooling Water@ 40 C
Hot Water @ 130 C
HydrideAlloy
Hydrogen In
1 Bar
Hydrogen Out
6 Bar
Step 1 Step 2
Hydride Beds are heated to compress the hydrogen, then cooled to accept the next volume of hydrogen.
[There are parallel beds, not shown here, which operate out of phase]
HydrideAlloy
1
HydrideAlloy
2
HydrideAlloy
3
HydrideAlloy
4
1.5 Bar 10.0 Bar 65 BarH2 inlet0.5 Bar
H2 output430 BarHigh Pressures are
achieved with Multiple stages using alloys with progressively elevated plateau pressures
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HERA Hydride Compressor Technology StatusErgenics (now HERA USA) held initial patents on hydride compressors
HERA has been supplying metal hydride hydrogen compressors for abroad range of applications for over twenty years
Current technology demonstrated to 550 bar (8000 psi) output pressure and 200 slpm (12 m3/hr) flow rateTechnology ready for product standardization and its commercialization is an essential part of HERA’s business plan
Technology development funded by the DOE Hydrogen and Fuel Cells Program over the 1999-2004 period (focused on impurity tolerance)
Second generation compressor design in progressModular design; elevated temp. operation
Larger capacity (1560 Nm3/hr); higher pressure (345 bar)
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Key Challenges to be Addressed
Membrane Reactor Hydride Compressor
Optimization of the efficiency of the hydride heat exchangersIntegration of low cost, high temperature heat sourceStandardization of the staging elements (for flow rates & pressures)
Optimization of membrane cost vs. performance / lifetimeDevelopment of lower cost mechanical design of system
Integrated SystemFull heat source integration between membrane reactor and hydride compressorSmooth operation of reformer with the cyclic operation of the compressor
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Work Planh Task 1 – Techno-economic evaluation (Apr – Sept. 05)
− Review / revise overall system requirements− Evaluate integration options and select the most promising scheme− Detailed design of Integrated reformer / compressor components− Economic analysis of Integrated system− Deliverable: Completion of techno-economic analysis report
4Recommendations for the POC construction and testing (Task 2)
h Task 2 – Proof of Concept prototype (Oct. 05 –Sept. 06)− Fabrication / assembly / testing− Deliverable: Report summarizing POC test results
h Task 3 – Advanced Prototype unit (Oct. 06 – Nov. 07)− Design / fabrication / assembly / testing / report
h Task 4 – Develop concept for mass production (Dec. 07 – Mar. 08)− Deliverable: Report providing final design to meet DOE targets
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Schematic of the Integrated System
MHC
Feedwater Pump
MembraneReactor
Burner
Vaporizer
Air Compressor
Air B lower
Cooler
PCV-100
To H2 Storage
Process A ir
DI W ater
Natural Gas
Combustion A ir
Hot Fluid Pump
Cold Fluid Pump
FluidHeater
Stack Gas
HotSideLoop
Fluid Cooler
ColdSideLoop
Product Cooler
NG Compressor
h Evaluating SMR vs. ATR options and various equipment configurationsh Excess heat from reformer section used for hydride regeneration
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Technical Accomplishments/Progress/Results
h Project kick-off meeting held with DOE personnel
h Project organization / decision making process defined
h Reformer/compressor integration being progressed
− Preliminary designs developed
− Integration options being reviewed
− Modeling, simulation and optimization in progress
− Economic analysis framework based on H2A
h Project Safety Review process being defined
H2E
Thank You!
Questions?
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Project Management
h BOC will provide overall project management by leveraging− Experience in operating industrial hydrogen plants and developing
customer solutions around these plants− In-depth knowledge of process integration and of customer needs− Culture of collaboration and team work to obtain results
h Team formed with technical and business representatives from BOC, MRT and HERA− Individual tasks will be led by area experts with participation from others− Regular meetings to review progress and make decisions
h BOC will coordinate communication with DOE with input from MRT and HERA− Submission of technical reports− Management of budget, invoicing, disbursement
h Upon successful completion of project BOC is committed to facilitate commercialization of the integrated system
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Safety Planning
h The most significant hydrogen hazard associated with this project is:− Fire or explosion due to exposure of hydrogen-containing combustible
gases to air and/or heat sources
h Our approach to deal with this hazard consists of the following:− Rigorous procedures developed by the team for this type of project will be
used. These include Technical Risk Assessment, Process Safety Review and HAZOP
− System design will incorporate safety shutdown protocols for all potential critical identified
− Project team is educated and trained on hydrogen safety and access to test equipment will be limited to trained personnel
h Other related activities will be leveraged− BOC actively participates in various Codes & Standards committees
− BOC has significant experience with H2 refueling station projects